Optical waveguide plug-in system for multimedia devices

ABSTRACT

A specification is given of an OWG plug-in system for multimedia devices comprising a first OWG plug connector ( 1 ) with a mechanically releasable connector ( 2 ) and a mating connector ( 3 ), the said OWG plug connector being arranged in proximity to a multimedia device, a second OWG plug connector ( 101 ) with an OWG connector ( 105 ) and a printed circuit board ( 102 ), this second OWG plug connector ( 101 ) being arranged in an electromagnetically compatible region of the multimedia device and containing at least one active element, and at least one OWG cable ( 40   b ), with an OWG connector ( 4   b   , 105 ) at each end, one OWG connector ( 4   b ) of which can be fixed into the first OWG plug connector ( 1 ) and the other OWG connector ( 105 ) of which can be fixed into the second OWG plug connector ( 101 ), in each case without play, the active element being arranged in a manner centred with respect to the OWG connector ( 105 ) in the second OWG plug connector ( 101 ).

The present invention relates to an OWG plug-in system for multimedia devices according to Patent claim 1.

Such plug-in systems can be used wherever there are optical signal transmissions. Thus, the transmission of information is effected via OWGs on account of the constantly increasing requirements made of the transmission rate (25 to 50 Mbit/s), for example in modern automobiles.

The printed documents DE 44 12 571 and DE 195 25 739 have disclosed OWG plug connectors which butt directly against an active element, for example a transceiver. This means that the active element is situated in the mating connector. For structural reasons, the OWG connector projects from the OWG plug connector. The OWG plug connector together with active element are usually fitted on the housing exterior of a multimedia device, such as e.g. a CD player, in order to minimize the attenuation between OWG connector and active element.

In this case, it is particularly disadvantageous that the interface between OWG and active element is arranged without any protection outside the device and is particularly susceptible to electromagnetic interference. This solution is unsuitable for the transmission rates required, since the EMC (electromagnetic compatibility) decreases as the transmission rate increases. Furthermore, it is disadvantageous that the OWG presses directly onto the active element, since, in the event of external mechanical influences, such as e.g. vibration, the optical surface may be damaged and attenuation is thus produced at the OWG conductor/active element junction.

Moreover, plug connectors have been disclosed in which the OWG connector butts against the active element and the two are subsequently potted jointly with epoxy resin.

In this case, it is particularly disadvantageous that, on the one hand, the connection between OWG connector and active element is no longer releasable and, on the other hand, as a result of material fatigue, the resin becomes dull, the fibre acquires hairline cracks or the connection tears completely, with the result that the attenuation becomes ever greater over time in the first and second cases and transmission is no longer possible in the third case.

The object of the invention is to specify a plug-in system for multimedia devices which, to the largest extent possible, is insensitive to EM interference without the plug-in system causing appreciable attenuation, in the process.

This object is achieved by means of the features specified in the independent claim.

The OWG plug-in system for multimedia devices comprises a first OWG plug connector with a mechanically releasable connector and a mating connector, the said OWG plug connector being arranged in proximity to a multimedia device, a second OWG plug connector with an OWG connector and a printed circuit board, this second OWG plug connector being arranged in an electromagnetically compatible region of the multimedia device and containing at least one active element, and at least one OWG cable, with an OWG connector at each end, one OWG connector of which can be fixed into the first OWG plug connector and the other OWG connector of which can be fixed into the second OWG plug connector, in each case without play, the active element being arranged in a manner centred with respect to the OWG connector in the second OWG plug connector.

In the case of plug connectors having a plurality of OWG cables, the OWG connectors may have lugs operating as codings which guarantee the capability of fitting the respective chambers.

It is preferable for the OWG connector which can be plugged into the first plug connector to be embodied as a “pigtail” for an active element. A “pigtail” is to be understood to mean an optical extension cable for an active element; in this case, the one end can be connected directly to the active element and the other element is preformed with a second OWG connector. This affords the possibility of banishing the active element from the mating connector and arranging it at a suitable location in terms of EMC. The plug connector is now independent of the development of the active element, with the result that the plug connector may survive a number of active element generations, since every new development of the active element may entail a development of a new mechanical interface between active element and OWG.

Further features and advantages of the invention emerge from the following description of an OWG plug connector as an example of a preferred configuration of the invention with reference to the schematic drawings, in which:

FIG. 1 shows an oblique plan view of a plug-in system having a first plug connector in the plugged-in state;

FIG. 2 shows an oblique plan view of a printed circuit board with a second plug connector;

FIG. 3 shows an oblique plan view of a plug-in system according to the invention having a first plug connector which is in the non-plugged-in state;

FIG. 4 shows a section along the plane E along the first plug connector from FIG. 1;

FIG. 5 shows a section along the line A—A of the plug connector from FIG. 4;

FIG. 6 shows an oblique plan view of the covering cap of the connector;

FIG. 7 shows an oblique plan view of the connector housing; and

FIG. 8 shows a vertical section through the second plug connector from FIG. 2.

The plug-in system according to the invention is illustrated in FIGS. 1 and 2, the first figure showing the first plug connector (1) and the second figure showing the second plug connector (101).

The structure of the first plug connector 1 is described in detail below.

The first plug connector 1 can be seen in an oblique plan view in the unplugged-in state in FIG. 3 and in the plugged-in state in FIG. 1. The first plug connector 1 is composed of at least four components, a connector 2, a mating connector 3 and at least two OWG connectors 4 a, 4 b. The connector 2 is partly cut away in FIG. 3 in order to illustrate its inner structure. The latter essentially has a first housing 6 with an electrical plug-in unit 38 and two first chambers 7, which are preformed with OWG connectors and are readily visible in the cut-out region in FIG. 3, as well as OWG cables 40 a associated with the OWG connectors 4 a, and a covering cap 5 pushed onto the housing 6.

The mating connector 3 essentially has a second housing 8, one end being provided with an insertion shaft 10, which is necessary for the connector 2. The opposite end of the second housing 8 on the one hand has two second chambers 9 and on the other hand may have an electrical mating plug-in unit 39 matching the electrical plug-in unit 38 and having correspondingly required electrically conductive connections. In FIG. 3, the electrical plug-in unit 38 is provided with four electrical connections. Both the electrical plug-in unit 38 and the electrical mating plug-in unit 39 are not part of the subject-matter of the invention.

The OWG connectors 4 a, 4 b can be roughly divided into four regions, a cylindrical end piece 11 a, 11 b, a centre piece (not described in any specific detail), an adjoining collar 18 a, 18 b with a square cross section, and the OWG cables 40 a, 40 b. The end piece 11 is bounded by the exit face 16, which is hot-plated, that is to say that this face is absolutely planar, with the result that hardly any attenuation is produced when the “light” exits or enters. As will subsequently become clear, the mating connector 3 must be preformed with the OWG connectors 4 b before the connector 2 is guided into the insertion shaft 10 until a latching lug 33 of the connector 2 snaps into a matching latching opening 33 of the mating connector 3, in order to lock the connector and the mating connector together.

It should be noted that all parts of the first OWG connector are provided with the reference symbol “a”. Correspondingly, the parts of the second OWG connector are identified by “b”. The two OWG connectors 4 a, 4 b differ only in terms of the coding lugs 12. The latter guarantee the capability of the OWG connectors to fit in the respective chambers.

FIG. 4 shows a section along the plane E of the plug connector from FIG. 1, FIG. 5 showing a section along the line A—A of the plug connector from FIG. 4. The electrical plug-in unit 42 is readily discernible in the left-hand region of the plug connector. Four chambers, which can each accommodate a female connector (not illustrated), are discernible in the upper region of this unit. In the lower region of the unit, the four female mating connectors 36 are fixedly anchored together with the second housing 8, the contact prongs of the female mating connectors 36 projecting into the chambers 41 provided in the first housing 6. The right-hand portion of the plug connector shows the OWG unit 43. Two first square chambers 7 are discernible in the upper region of this unit, an OWG connector 4 a being situated without play in each of the said chambers. In order to provide a better understanding, the OWG cable 40 a has not been illustrated as well. The OWG connector 4 a on the one hand rests with its lug 12 a on the stop 24 a and, on the other hand, this connector is secured by the guide rail 28 in the vertical direction, the end face 29 of the guide rail 28 resting on the collar 18 a (see FIG. 4). The side areas of the collar 18 a and of the centre part are guided by the side walls of the chamber 7. Furthermore, the exit face 16 a of the cylindrical end piece 11 a projects into the hole 23, the wall 25 of the hole 23 centring this end piece.

Two chambers 9 with a square cross section, which are provided in the housing 8 of the mating connector 3, can likewise be seen in the lower region of the OWG unit. One wall of the chamber is designed as an elastic securing arm 13, the latter having a latching lug whose end 21 is inwardly bevelled, and the rear side 22 of the latching lug running transversely with respect to the plugging direction, with the result that the OWG connector 4 b is captively secured in the chamber 9. Two further walls of the chamber 9 are designed as elastic latching arms 14, whose free ends have latching lugs 15 on the side facing the chamber, which latching lugs have, as seen in the plugging direction, a bevelled end 19 and a bevelled rear side 20 in each case (see FIG. 4). In order to strengthen the elastic spring force of the latching arms 14, elastic elements 26 are arranged between the second housing 8 and the free ends of the latching arms. The fourth wall of the chamber 9 is designed as a rigid guide wall.

As already mentioned, the connector 2 is not situated in the insertion shaft 10 during the preforming of the mating connector 3 with OWG connectors 4 b. When the OWG connector 4 b is pushed into the chamber 9, the latching arms 14 and the securing arm 13 are spread apart until the collar 18 b has surmounted the ridge of the latching lugs 15, with the result that the latching arms 14 can snap back and the rear side 22 of the securing arm 13 is situated parallel to the collar area. When the latching arms 14 snap back, the bevelled rear side 20 presses against the collar 18 b, with the result that a force acts upwards and holds the OWG connector 4 b against the stop 24 b. During this operation, the collar area 18 b is removed from the rear side 22 of the securing arm 13.

When the connector is inserted into the mating connector 3, the end piece 11 b dips into the hole 23 in the connector 2 until the wall 25 of the hole reaches the lug 12 b, a defined gap thereby being produced between the exit faces 16 a, 16 b. As the connector 2 is inserted further, the OWG connector 4 b is pressed downwards by the wall 25 counter to the spring forces of the latching arms 14, until the connector 2 latches into place in its final position. It should be noted that the gap 34 is independent of the tolerances of the locking mechanisms, such as e.g. securing arm 13, latching arms 14, etc. The gap is defined only by the spacings between the edge of the lug 12 a, 12 b and the exit faces 16 a, 16 b and by the diameter of the hole 23. These dimensions are very small in terms of production engineering, so that the gap hardly varies due to production. As a result, the gap can be chosen to be as small as possible in order to avoid unnecessary attenuation. In addition, the hole 23 ensures that the exit faces are arranged parallel to one another. In interaction with the longitudinal play of the lower OWG connector 4 b and the bevelled rear sides 20 of the latching lugs 15, a pressure is produced between the wall 25 of the hole 23 and the lug 12 b, a firm fit thereby being ensured for the lower OWG connector 4 b.

A covering cap 5 with an annular cable outlet can be seen in an oblique plan view in FIG. 6, the said cable outlet having a shoulder 37 and a latching lug 32 on the outer area along the plug-in device. Inside the covering cap, an L-shaped guide rail 28 is integrally formed transversely with respect to the plugging direction, and so, too is a latching element 30 which is wedge-shaped transversely with respect to the plugging direction.

FIG. 7 shows a first housing of the connector 2 in an oblique plan view. On the connector side it is possible to see, on the one hand, the openings of the chambers of the female mating connectors and, on the other hand, the square walls 25 of the hole 23. Behind these elements there is a guide groove 44 on the top side of the housing, which guide groove runs transversely with respect to the plug-in direction and has a wedge-shaped latching element 31. A longitudinal opening 27 which likewise runs transversely with respect to the plugging direction has been made in the top side of the housing.

During the assembly of the connector 2, firstly the chambers 7 have to be occupied by the corresponding OWG connectors 4a together with cables 40 a. Only then can the covering sleeve 5 be pushed onto the housing 6, the L-shaped guide rail 28 passing into the longitudinal opening 27, with the result that the end of the L slides along the collar 18 a until the latching elements 30 and 31 lock the system.

FIG. 2 shows a printed circuit board equipped with an OWG plug connector 101, into which two OWG connectors 105 are plugged. The base region 121 of the plug connector 101 is provided with a screen 122 having connecting pins 124 in order to be electrically connected to the printed circuit board 102. The fact that the screen has a cutout for the connecting pins 109 of the active element on one side area is readily discernible in FIG. 2.

FIG. 8 shows a vertical section through the plug connector 101. The plug connector comprises three parts. Two chambers 104 for accommodating OWG connectors 105 are discernible in the upper region. The walls of the chamber are embodied as elongate latching arms on whose free ends latching lugs are integrally formed, whose ends are bevelled towards the chamber and the rear side runs transversely with respect to the plug-in direction.

Two cavities 112 are discernible in the lower region of the plug connector, the so-called base region 121, elastic centring shoulders being integrally formed on the inner walls of the cavity 112. The said shoulders centre an active element 113 situated in the cavity 112 in such a way that the active region of the active element 113 is situated in the axis of symmetry of the chamber 104. The chambers and the cavities 112 are connected to one another via holes 106.

When an OWG connector 105 is plugged into the chamber 104, the elongate latching arms 108 spread apart until the lug 123 of the OWG connector 105 butts against the stop 146, the latching arms thereby attaining the locking position, the rear side 120 of the latching lug reaching the collar 147 of the OWG connector 105. As the OWG connector 105 is inserted, the end piece 111 penetrates the hole, the end piece 111 projecting into the cavity 112 in the locking position, a defined spacing being produced between the active region of the active element 113 and the exit face 110. This spacing should be minimized, it being necessary to ensure that the active region and the exit face cannot touch one another under any circumstances.

It should be noted that the spacing is independent of the tolerances of the locking mechanisms. The spacing is defined only by the spacings between the edge of the lug 123 of the exit face 110, and the diameter of the hole 106. These dimensions are very small in terms of production engineering, so that the spacing hardly varies due to production. As a result, the spacing can be chosen to be as small as possible in order to avoid unnecessary attenuation.

Furthermore, the outwardly directed walls of the cavity have a perforation 117, which enables the connecting pins 109 of the active element 113 to be routed outwards. The lower region of the plug connector 101 has the printed circuit board 102, which has continuous openings 107 a, 107 b. The connecting pins 109 of the active element 113 and the connecting pins 124 of the screen 112 are led through the said openings. Furthermore, the latching feet 108 of the housing 103 are led through the opening 107 b in order to fixedly connect the plug connector 101 to the printed circuit board 102.

This plug-in system has made it possible for the externally accessible connections to continue to be arranged on the housing exterior of a multimedia device, and the first plug connector 1, in particular, is provided for this purpose. It has now become possible for an active element 113 which is sensitive to EM interference to be arranged in an EMC region with the aid of the second plug connector. The optical connection between active element 113 and the first plug connector is achieved by using a pigtail. As already mentioned, the latter is understood to mean an optical extension cable 40 b, the latter having an OWG connector at both ends. These connectors are simply plugged into their corresponding chambers 9 and 104, respectively. 

What is claimed is:
 1. OWG plug-in system for multimedia devices, comprising a first OWG plug connector with a mechanically releasable connector and a mating connector, the said OWG plug connector being arranged in proximity to a multimedia device, a second OWG plug connector with an OWG connector and a printed circuit board, this second OWG plug connector being arranged in an electromagnetically compatible region of the multimedia device and containing at least one active element, and at least one OWG cable, with an OWG connector at each end, one OWG connector of which can be fixed into the first OWG plug connector and the other OWG connector of which can be fixed into the second OWG plug connector, in each case without play, the active element being arranged in a manner centred with respect to the OWG connector in the second OWG plug connector.
 2. OWG plug-in system according to claim 1, characterized in that the second OWG plug connector is provided with a shielding having connecting pins which are electrically connectable to the printed circuit board. 